The answer of @user2818943 is good, but it can be optimized a little:

```
def divergence(F):
""" compute the divergence of n-D scalar field `F` """
return reduce(np.add,np.gradient(F))
```

Timeit:

```
F = np.random.rand(100,100)
timeit reduce(np.add,np.gradient(F))
# 1000 loops, best of 3: 318 us per loop
timeit np.sum(np.gradient(F),axis=0)
# 100 loops, best of 3: 2.27 ms per loop
```

About 7 times faster:
`sum`

implicitely construct a 3d array from the list of gradient fields which are returned by `np.gradient`

. This is avoided using `reduce`

Now, in your question what do you mean by `div[A * grad(F)]`

?

- about
`A * grad(F)`

: `A`

is a 2d array, and `grad(f)`

is a list of 2d arrays. So I considered it means to multiply each gradient field by `A`

.
- about applying divergence to the (scaled by
`A`

) gradient field is unclear. By definition, `div(F) = d(F)/dx + d(F)/dy + ...`

. I guess this is just an error of formulation.

For `1`

, multiplying summed elements `Bi`

by a same factor `A`

can be factorized:

```
Sum(A*Bi) = A*Sum(Bi)
```

Thus, you can get this weighted gradient simply with: `A*divergence(F)`

If ̀`A`

is instead a list of factor, one for each dimension, then the solution would be:

```
def weighted_divergence(W,F):
"""
Return the divergence of n-D array `F` with gradient weighted by `W`
̀`W` is a list of factors for each dimension of F: the gradient of `F` over
the `i`th dimension is multiplied by `W[i]`. Each `W[i]` can be a scalar
or an array with same (or broadcastable) shape as `F`.
"""
wGrad = return map(np.multiply, W, np.gradient(F))
return reduce(np.add,wGrad)
result = weighted_divergence(A,F)
```

`O(h)`

or`O(h**2)`

, and what is the spacing? ... – mgilson Jul 11 '12 at 15:54